EP0410076B1

EP0410076B1 - Inverted port engine with cross-under intake passage

Info

Publication number: EP0410076B1
Application number: EP90106249A
Authority: EP
Inventors: Kevin G. Bonde
Original assignee: Tecumseh Products Co
Current assignee: Tecumseh Products Co
Priority date: 1989-07-12
Filing date: 1990-03-31
Publication date: 1992-09-30
Also published as: US4926813A; EP0410076A1; DE69000358T2; AU625474B2; CA1319867C; AU5886990A; DE69000358D1

Description

The field of the invention is that of L-head internal combustion engines. More particularly, the invention relates to L-head internal combustion engines having a cast cylinder assembly and an intake cross-under passage.
One arrangement of a prior art L-head internal combustion engine, which is sometimes referred to as a side valve engine, comprises a crankshaft disposed vertically which reciprocates with a horizontally disposed piston. The cylinder includes intake and exhaust valve cavities located relatively closely on one side of the cylinder, with the intake valve positioned above the exhaust valve. The valves have a parallel orientation relative to the piston bore, with their heads and seats located near the head of the cylinder in communication with the piston bore and the spark plug. The intake valve periodically opens to create a passageway connecting a carburetor and the piston bore, with the passageway including the intake cavity near the cylinder head. Similarly, the exhaust valve periodically opens a passageway connecting the piston bore and an exhaust system, which includes a muffler, with the passageway including an exhaust cavity near the cylinder head. A common camshaft located within the crankcase lifts and opens the valves.
Although the intake and exhaust valves are disposed on a common side of the cylinder, locating the carburetor and the exhaust system on opposite sides of the engine provides a number of benefits. One benefit is that the carburetor is not exposed to the exhaust heat from the exhaust system, which minimizes negative consequences which result when the carburetor is excessively heated. Another benefit relates to separating the carburetor fuel lines from the muffler to avoid the potential hazard from having the fuel too close to a heat source.
To achieve these and other benefits, prior art engines, as described for example by US-A-3 118 433, Fig. 4, route an external intake tube from the intake valve, over the cylinder, to the carburetor located on the opposite side. Locating the intake valve above the exhaust valve results in less efficient cooling of the exhaust because the exhaust cavity is less exposed to the flow of cooling air which circulates more about the upper sections of the engine. In addition, the intake system insulates the exhaust system, inhibiting the dissipation of heat because the rising heat from the exhaust system is trapped by the components of the intake system. Further, routing the intake tube over the cylinder requires that the carburetor be mounted relatively high with respect to the mounting base of the engine. This restricts the space available above the carburetor to accommodate a gravity feed fuel tank, constraining the volume of the tank if the height of the engine is unchanged. Alternatively, a larger fuel tank can be provided, but that requires the undesirable result of increasing the height of the engine.
A solution to the aforementioned problems involves routing the intake passageway, formed within the cylinder block, under the cylinder, as disclosed in US-A-4893 597 published 16. Jan 1990. This arrangement allows for better ventilation for the exhaust system while not restricting the space available for a fuel tank. However, providing an integrally formed intake passageway within the cylinder entails extra manufacturing steps and cost. Also, the intake system buried within the block absorbs heat from the block, reducing the overall volumetric efficiency.
What is needed in the art is an engine that realizes the advantages of a cross-under intake passageway underneath the cylinder while minimizing the cost and without absorbing the excess heat which reduces the efficiency.
The present invention is an inverted port L-head engine having a carburetor port in the cylinder block opposite the exhaust side of a cylinder and to which the carburetor is connected, with a cross-under U-shaped tube providing an intake passage which connects said carburetor port to the intake valve which is positioned on the exhaust side. The cast cylinder has the intake valve positioned below the exhaust valve, with downwardly facing openings in the cast cylinder for slidably receiving ends of the cross-under tube. One opening is located near the intake valve, with the other opening disposed on the other side near a carburetor mounting port block. The openings and the mounting port block are die cast in the cylinder.
The present invention achieves simplicity and economy by minimizing the number of parts required to provide a cross-under intake passageway, in that only the single cross-under tube is needed to provide an airtight passage from the carburetor to the cylinder. No O-rings, gaskets, mounting screws, or other additional parts are involved in connecting the cross-under tube to the cylinder block, rather an interference fit secures the tube within the openings of the cast cylinder. Alternately, a single mounting screw can be used to mechanically fasten the tube to the cylinder. Assembling the engine is quick and easy as the only step necessary to attach the cross-under tube is to insert the tube ends into the cast cylinder's openings. Preferably, a liquid sealant can be used to provide a seal to insure the passageway is airtight.
In addition, the carburetor is more securely attached to the engine of the present invention. In some prior art engines, the carburetors are positioned somewhat independently of the cylinder when a separate tube connects the two. Thus, the carburetor is subject to being moved in its position relative to the cylinder, changing the shape and/or size of the intake passageway resulting in a diminished performance. A carburetor mounting port block integrally formed within one side of the cast cylinder so that the mounting is rigid and requires no gauging to mount the carburetor. Such a stable mounting surface provides accurate location for attaching the carburetor, to improve the efficiency and stability of the intake side of the cylinder.
The aerodynamically smooth shape of the cross-under tube also improves the efficiency of the engine. Although the cross-under tube extends around the cylinder, it has gentle bends which induce a more laminar flow of combustion fluids to the intake valve. By providing such an intake passageway, turbulence is minimized and the breathing of the engine is improved thus making the engine more efficient.
The present invention, in one form thereof, comprises an inverted port vertical shaft internal combustion engine having a carburetor, an exhaust system, and a cylinder assembly. The cylinder assembly includes a cylinder block comprising a single cylinder with a piston bore, an intake cavity and valve, and an exhaust cavity and valve. The exhaust cavity has an exhaust port and is located proximate to and above the intake valve cavity on a first side of the cylinder. Also on the cylinder is a downwardly facing first opening located below the intake valve cavity on the first side, a downwardly facing second opening located on the second side, and a carburetor port is also located on the second side. The first opening is in communication with and located near the intake cavity, and the second opening is in communication with the carburetor port. Connected to the cylinder block is a cross-under tube which has a first end and a second end received in the cylinder block. The cross-under tube has a U-shape and its first and second ends are relatively parallel, with the first end and the second end of the cross-under tube being slidably received in the first and second openings, respectively, of the cylinder. Further, the cross-under tube is connected and sealed to the cylinder block so that they provide an intake passage from the carburetor port to the intake valve cavity. The carburetor is disposed on the second side and is connected to the carburetor port, while the exhaust system is disposed on the first side and is connected to the exhaust port.
One object of the present invention is to provide a cylinder assembly which is both simple to construct and economically efficient. Another object of the present invention is to provide an improved design for an inverted port engine.
The above mentioned and other objects of this invention, and the manner of attaining them, will become more apparent and the invention itself will be better understood by reference to the following description of and.embodiment of the invention taken in conjunction with the accompanying drawings, wherein:
Figure 1 is a front elevational view of a lawn mower having an engine of the present invention.
Figure 2 is a front sectional view of the engine of the present invention.
Figure 3 is an enlarged sectional view of the outlined area 3 of Figure 2.
Figure 4 is a sectional view taken along view line 4-4 of Figure 2 in the direction of the arrows.
Corresponding reference characters indicate corresponding parts throughout the several views.
The present invention is a cylinder assembly for an inverted port L-head internal combustion engine. It is used, for example as in Figure 1, to drive a cutting blade (not shown) of a lawn mower 6. Lawn mower 6 comprises a deck 8 covering the blade and having axles 10 rotatably connected with wheels 12; the axles 10 extending from sides near the bottom of deck 8. Mounted on deck 8 is L-head engine 14, which comprises a carburetor 16, a cylinder block 18, a cylinder head 20, a cross-under tube 22, and an exhaust system 24. Above those components of engine 14 are blower housing 26, a gravity feed fuel tank (not shown), above which is starter housing 27 from which extends pull handle 28 attached to a flywheel pulley (not shown). The remaining components of engine 14 (e.g. vertical crankshaft and camshaft, crankcase, piston, etc.) are well known and consequently are omitted for the sake of clarity in the following description.
Cylinder head 20 covers much of the front of cylinder block 18, and is connected by head bolts 30 which are received in bolt holes 32 of cylinder block 18 (see Figure 2). Also, spark plug 34 is positioned so that it extends through cylinder head 20, and operates in a known manner.
Referring to Figure 2, the configuration of exhaust valve 36 above intake valve 38 causes L-head engine 14 to be termed an "inverted port" engine, as opposed to engines which have the intake valve over the exhaust valve. When closed, exhaust valve 36 and cylinder block 18 define exhaust cavity 40, and intake valve 38 and cylinder block 18 define intake cavity 42. Valves 36 and 38 open alternately, with an open exhaust valve 36 allowing products of combustion to exit from a combustion chamber (not shown) above piston bore 44 of cylinder 45, and an open intake valve 38 allowing a combustion mix to enter the combustion chamber and piston bore 44. The exiting products of combustion flow past valve 36, through the exhaust cavity 40, to the attached exhaust system 24 which comprises a muffler and, if needed, associated piping. The intake combustion mix is drawn from carburetor 16 through intake cavity 42, past valve 38, and into the combustion chamber.
The present invention concerns a novel arrangement for providing an air/fuel combustion mix from carburetor 16 to cylinder block 18. Integrally formed within cylinder block 18 is a carburetor port block 46 which provides a rigid, accurate support for directly mounting carburetor 16, and associated intake system components, to cylinder block 18. Carburetor port block 46 is located on a side of cylinder block 18 opposite valves 36 and 38, and includes intake chamber 48. In communication with intake chamber 48, an opening 50 is integrally formed within cylinder block 18, preferably by machining, to receive end 52 of cross-under tube 22. End 52 slidably engages opening 50, preferably forming an interference fit within opening 50.
Passage 54, defined by inner walls of cross-under tube 22, provides fluid communication between carburetor 16 and intake valve 38; cross-under tube 22, hence passage 54, extends under cylinder block 18. Opening 56, which is integrally formed within cylinder block 18 and in communication with intake cavity 42, receives end 58 of cross-under tube 22 to complete passage 54. Preferably, opening 56 is machined in cylinder block 18 and engages end 58 to form an interference fit.
Cross-under tube 22 is U-shaped and has an aerodynamic contour which facilitates providing a continuous, uniform flow of air/fuel combustion mix, thus improving the efficiency of the engine. Ends 52 and 58 are vertical and mutually parallel, with both extending downwardly to form bends 60 and 62, respectively. The bends are not sharp right hand angles that tend to cause turbulence. Rather, bends 60 and 62 have a generally curvilinear shape both of which eventually straighten to form straight section 64 of cross-under tube 22. This curvilinear shape promotes laminar flow within cross-under tube 22, eliminating much of the turbulence which interferes with the flow of a combustion mixture within passage 54 thus increasing the efficiency of engine 14.
To build L-head engine 14, carburetor 16, cylinder block 18, cylinder head 20, exhaust system 24, etc., are assembled in a conventional manner. To connect cross-under tube 22 to cylinder block 18, end 52 is positioned in opening 50 and end 58 is positioned in opening 56. The straight section 64 of cross-under tube 22 is then pushed upwardly to force ends 52 and 58 deeper into their respective openings 50 and 56. The U-shaped contour of cross-under tube 22 facilitates its assembly because with the parallel ends 52 and 58, a single push in the axial direction of ends 52 and 58 slip the cross-under tube 22 securely in place. In the preferred embodiment, cross-under tube 22 comprises bent steel tubing; alternately, cross-under tube 22 can be of plastic construction, either blow molded or injection molded using a metal core that melts out at relatively low temperatures. The resiliency of ends 52 and 58 of cross-under tube 22 and the structure forming openings 50 and 56 enable the interference fit to be formed.
Referring to Figure 3, a preferred technique for sealing cross-under tube 22 to openings 50 and 56 is shown. A liquid sealant 66, which ensures an airtight sealing of passage 54, is placed on ends 52 and 58 of cross-under tube 22, or receiving walls 68 of cylinder block 18, to seal and hold cross-under tube 22 in place. A tapered region 70 in receiving wall 68 provides space for excess sealant 66 and assists in guiding cross-under tube 22 in place. The sealant is preferably a low viscosity anaerobic type which will penetrate the joint and form a seal in the absence of air, but other types of sealants, such as silicone based caulk, can be used.
Referring to Figure 4, a bracket 72 is provided to position and retain cross-under tube 22 properly. Bracket 72 is mounted on cylinder block 18 by screw 74 below piston bore 44 after attaching cross-under tube 22 to cylinder block 18. Bracket 72 provides an additional (or possibly alternate) structure for retaining cross-under tube 22, as a single fastener can be used when the amount of interference alone is insufficient to retain tube 22 securely.
Alternate means can be used to ensure the retention of tube 22 to block 18. For example, tube 22 can be press fit into openings 50 and 56. Also, a single screw or a press fit/screw combination can provide an adequate connection, preferably in combination with a bracket. Additionally, a combination adhesive/sealant, such as high temperature epoxy, can be utilized. Further, soldering or brazing can provide a connection for tube 22.

Claims

An inverted port internal combustion engine (14), having a vertical crank shaft, further comprising a cylinder block (18) including a single horizontal cylinder having a piston bore (44), a first vertical side and a second vertical side diametrically opposite said first vertical side, said cylinder block having an exhaust port on the first vertical side, an intake cavity (42) receiving an intake valve (38), an exhaust cavity (40) receiving an exhaust valve (36), both of said cavities being formed on the first vertical side, said exhaust cavity having said exhaust port therein and being located proximate said intake cavity on said first vertical side, the engine further having an exhaust system (24) disposed on said first vertical side and connected to said exhaust port, and a carburetor (16) disposed on said second vertical side; the cylinder block further comprising a first opening (56) located on said first vertical side, said first opening (56) being in communication with and near said intake cavity (42); the engine further having a tube (22) connected to said cylinder block (18), said tube (22) having a first end (58) slidably received in said first opening (56) of said cylinder block (18) and said second end being in communication with said carburetor; the engine further comprising means (66, 68, 70) connecting and sealing said tube (22) to said cylinder block (18), characterized in that the cylinder block has on the second vertical side a carburetor port to which said carburetor is connected, and a second opening (50) located on said second vertical side and in communication with said carburetor port, the second end of said tube being slidably received in said second opening (50) of said cylinder block (18); in that said exhaust cavity (40) is located above said intake cavity (42); in that said first (56) and second openings (50) face downwardly, the first opening (56) being located below said intake cavity (42); and in that the tube (22) is a cross-under tube which is U-shaped, with said first (58) and second (52) ends relatively parallel, such that said tube (22) and said cylinder block (18) provide an intake passage from said carburetor port to said intake cavity".
The engine of Claim 1 characterized in that said cross-under tube (22) is located under said cylinder block (18) and said piston bore (44).
The engine of Claim 1 characterized in that said means (68) for connecting and sealing said cross-under tube (22) and said cylinder (18) comprises an interference fit.
The engine of Claim 1 characterized in that said means (68) for connecting and sealing said cross-under tube and said cylinder comprises a sealant (66) disposed between said first and second ends of said tube and said first and second openings, respectively.
The engine of Claim 1 characterized in that said first and said second openings (56, 50) include a tapered region (70).
The engine of Claim 1 characterized in that said cross-under tube (22) has a smooth aerodynamic shape without sharp bends for promoting laminar flow through said intake passage (54).
The engine of Claim 1 characterized by a bracket (72) mounted on the underside of said cylinder to position and retain said cross-under tube.
The engine of Claim 1 characterized in that said cross-under tube (22) has first and second bends (62, 60) with a gentle curvilinear shape promoting laminar flow through said passage.